Installation and method for vacuum treatment or powder production

ABSTRACT

Vacuum treatment installation with a vacuum treatment chamber containing a plasma discharge configuration as well as a gas supply configuration. The plasma discharge configuration has at least two plasma beam discharge configurations with substantially parallel discharge axes and a deposition configuration is positioned along a surface which extends at predetermined distances from the beam axes and along a substantial section of the longitudinal extent of the discharge beam.

FIELD AND BACKGROUND OF THE INVENTION

[0001] The present invention builds on a method for vacuum treatment according to the preamble of claim 9 or on a method for producing powder according to that of claim 10.

[0002] According to the present invention a vacuum treatment installation is obtained according to the preamble of claim 1 as well as use of the same according to claim 8.

[0003] The present invention, in principle, has the objective of reactively depositing plasma-enhanced, i.e. through a PECVD method, materials on a deposition surface, be these materials which generally are extremely difficult to produce, namely metastable materials such as cBN, α-Al2O3, C3N4 or, in particular, diamond materials, or basically materials at maximally high deposition rates and at maximally low temperatures, in particular when Si-containing compounds, further particularly microcrystalline μC—Si:H, are to be deposited.

[0004] EP 0 724 026 by the same applicant as the present invention, corresponding to U.S. Pat. No. 5,753,045, discloses a method for the vacuum treatment of at least one workpiece, in which the workpiece is exposed in a vacuum atmosphere to a reactive gas excited by means of a plasma discharge. The workpiece surfaces to be coated are disposed offset with respect to the plasma beam axis such that thereon a plasma density obtains of maximally 20% of the maximum density obtaining in the plasma beam axis. This procedure permits deposition layers difficult of production, in particular those comprising metastable materials in particular of diamond, cBN, α-Al₂O₃ or C₃N₄. With respect to the definition of “metastable materials”, reference is made to “Lehrbuch der anorganischen Chemie”, Hohlemann-Wiberg, Walter Gruyer, Berlin, New York 1976, Edition 81-90, p. 183 ff.

[0005] According to the Swiss Patent Application 794/99 by the same applicant as the present invention, it has been recognized that said method—according to EP 0 724 026—surprisingly is also suitable for high-rate coating of surfaces, on the one hand, and for generating powder or cluster-form material on a collection surface, on the other hand.

[0006] Of disadvantage in these prior known processes is that therewith, on the one hand, only workpiece surfaces of relatively small, in particular planar, dimensions can be homogeneously treated, in particular coated, but that, on the other hand, it would be entirely desirable to increase the quantity of powder or clusters generated per unit time. Consequently, it would be desirable to realize, in particular for diamond coating, a relatively large-area, uniform layer thickness distribution also at maximally high coating rates.

SUMMARY OF THE INVENTION

[0007] The objective of the present invention is to attain such.

[0008] For this purpose the method according to the invention for the treatment of workpieces—also as a basis for the installation according to the invention is distinguished thereby that in the vacuum atmosphere at least two plasma beams with substantially parallel beam axes are generated and that the at least one workpiece surface to be treated is disposed along a surface in the vacuum atmosphere on which the plasma density distribution, predetermined by the plasma beams, is generated. The method for production according to the invention is, on the other hand, distinguished thereby that in the vacuum atmosphere at least two plasma beams are generated with substantially parallel beam axes and a collection surface for the powder is disposed in the vacuum atmosphere such that on it a plasma density distribution predetermined by the plasma beams is generated.

[0009] It was found that in the prior known approach, in particular due to its cylindrical symmetry with respect to the axis of the one plasma beam, complex dependencies result of the concentration of reactive species on the radial distance from the beam axis. If in particular the local concentration, of critical importance for the generation of diamond material, of atomic hydrogen in the prior known approach and as a function of the radial distance from the plasma beam axis is considered, a model calculation according to FIG. 1 shows the concentration decrease with increasing radial distance, with the assumption of a linear distance dependence according to (a) and with the assumption of a quadratic distance dependence according to (b).

[0010] As explained, in FIG. 1 the concentration function is depicted along a plane E which is at a distance x_(min) parallel to the plasma beam axis A and viewed along a straight line G in plane E perpendicular to the beam axis A. The distance measure is normalized with x_(min), the concentration measure with respect to the maximum concentration on plane E at site S of distance x_(min).

[0011] Based on this representation, the reason is evident of why the prior known procedure with respect to deposition rate distribution presents problems, especially with relatively large workpiece areas to be coated if the one workpiece surface under consideration, or the several workpieces, is (are) each not disposed with their corresponding surface in such a way that they are rotationally symmetric about the beam axis A.

[0012] These problems are significantly reduced through the method proposed according to the invention.

[0013] Definitions

[0014] In the present specification the expression “workpiece support surface” is used if, according to the invention a workpiece treatment, in particular coating, is being addressed. The expression “collection surface” is used if powder or cluster generation is being addressed. The general term “deposition surface or “deposition configuration” is used if a “workpiece support surface” as well as also a “collection surface” jointly are being addressed.

[0015] In an especially preferred embodiment of the method according to the invention, onto the deposition surface a metastable material is deposited, preferably cBN, α-Al2O3, C3N4 or, especially preferred, diamond.

[0016] In a further preferred embodiment of the method according to the invention, a silicon compound is deposited onto the deposition surface preferably microcrystalline silicon μC—Si:H, and as a reactive gas silane is preferably employed.

[0017] In a preferred embodiment the plasma beams are realized as low-voltage arc discharges, highly preferred as high-current arc discharges, preferably by means of cold cathode discharges, but especially preferred by means of hot cathode discharges.

[0018] Further, the deposition surface is disposed in the vacuum atmosphere and with respect to the plasma beams such that along this surface predetermined minimum plasma density fluctuations occur. This is attained in particular thereby that along said deposition surface plasma densities of maximally 20% occur, preferably of maximally 10%, preferably even of maximally 5% of the plasma density maxima of the particular closest plasma beams, wherein further the plasma beams can be operated identically, i.e. in this case have substantially identical maximum plasma densities in their axes. But it is advantageous to optimize the plasma density distribution attained along deposition surfaces, for example of predetermined shape, through the specific tuning of the particular discharges, i.e. through the specific tuning of the beam-specific maximum plasma densities. For this purpose it is further proposed that the plasma beam discharges can be operated independently of one another, which opens the feasibility of carrying out said optimization specifically from case to case.

[0019] It was additionally and surprisingly found that with the proposed method a material deposition at very high deposition rates can be realized at temperatures at the deposition site of maximally 500° C. Accordingly, the methods according to the invention are preferably carried out such that by disposing the deposition surface such that the plasma density maxima obtaining on it are 20% of the closest beam plasma density maxima, a deposition rate on the deposition surface of minimally 400 nm/min is set up, preferably at said temperature of maximally 500° C.

[0020] In a further preferred embodiment, the plasma density distribution is tuned by means of at least one magnetic field parallel to the beam axis.

[0021] In a further preferred embodiment the plasma density distribution is tuned by means of at least one magnetic filed parallel to the beam axes.

[0022] In a further preferred embodiment a gas flow is established substantially parallel to the beam axes.

[0023] In order to equalize even further the treatment effect, in particular the coating thickness distribution, on several workpieces to be treated, which can be of significance in particular in workpiece surface treatment, it is further proposed that the workpieces are rotated about axes of rotation and/or moved linearly at least approximately parallel to the beam axes, preferably are moved in pendulum motions back and forth.

[0024] It was furthermore found that with the procedure according to the invention even further effectivity can be attained with respect to simultaneously treatable workpieces or deposited quantity of powder thereby that at least one first deposition surface is disposed between the plasma beams and at least a second deposition surface between the plasma beams and the wall of a treatment chamber with the vacuum atmosphere.

[0025] While, consequently, on the first deposition surface, which is between the plasma beams, material is deposited bilaterally, be that for obtaining powder or workpiece coating, on the second deposition surface material is deposited on only one side, be this again for obtaining powder or for treatment, such as in particular coating, of workpieces. With respect to workpieces, consequently, workpieces to be coated bilaterally or multilaterally, such as milling tools or drills, can be disposed along the first deposition surface, whereas workpieces, which require treatment, in particular coating, on only one side, such as indexable inserts, can be disposed along the second deposition surface. This increases decisively the efficiency of the method or of an installation provided for this purpose.

[0026] An installation according to the invention is now distinguished by the characterizing clause of claim 1. Preferred embodiments of this installation are specified in claims 2 to 7, uses of this installation in claim 8.

[0027] The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and specific objects attained by its uses, reference is made to the accompanying drawings and descriptive matter in which a preferred embodiment of the invention is illustrated.

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] In the following, the invention will be explained by example in conjunction with further FIG. s and examples. Therein depict:

[0029]FIG. 1 shows the concentration decrease with increasing radial distance for atomic hydrogen according to a model calculation assuming the linear distance dependence in curve (a) and assuming quadratic distance dependence in curve (b).

[0030]FIG. 2 is an installation according to the invention for carrying out the methods according to the invention schematically in side view;

[0031] FIGS. 3 to 6 again schematically, in top view, configurations according to the invention of plasma beams and deposition surfaces on installations according to the invention for carrying out the methods according to the invention;

[0032]FIG. 7 as a function of a measure of length along a straight line extending through the beam axis of two plasma beams, and perpendicular with respect to it, and parameterized with the heating current I of a hot cathode low voltage discharge, the plasma density distribution as well as (d) the plasma density distribution resulting on a planar deposition surface, parallel to and spaced apart from the beam axes; and

[0033]FIG. 8 in a representation analogous to FIG. 1, the modeled plasma density distribution according to the invention along a planar deposition surface parallel to and spaced apart from two provided plasma beam axes.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0034]FIG. 2 shows schematically in longitudinal section an installation according to the invention for carrying out the methods according to the invention.

[0035] In a vacuum chamber 1 at least two, as in FIGS. 3 to 6 at least six, plasma beams 3 are generated. As also shown in FIG. 2, they are preferably formed by a high-current low-voltage discharge on corresponding discharge gaps, preferably in each instance with a hot cathode 5, heated directly or indirectly, as shown preferably heated directly via a heating current circuit with heating current IH. The hot cathodes 5 are operated in a cathode chamber configuration 8, for examples as shown in FIG. 2, with individual cathode chambers 8 a, into which (not shown) a working gas, such as for example argon, is allowed to flow, and which via nozzles 7 communicate with the interior of the chamber 1.

[0036] But, in principle, for generating the plasma beams other cathode types can also be employed, such as, for example, hollow cathodes if high-purity coatings are to be generated and the generation of impurities through sublimated hot cathode atoms is to be prevented.

[0037] In FIG. 2, 9 denotes further the discharge gap anodes and 11 the discharge generators.

[0038] Between the plasma beams 3, in the configuration according to FIG. 2 preferably at least six such, of which three are evident, are provided deposition configurations along one or several surfaces 13, which extend at predetermined distances from the beam axes A between the plasma beams 3, corresponding to the desired plasma density distributions on these surfaces 13 and thus on the deposition configuration. The deposition surfaces 13 are defined by workpiece support surfaces in the workpiece treatment according to the invention, for receiving one or several workpiece(s), or they are formed by collection surfaces, if, according to the invention, a powder or cluster generation is intended at these surfaces.

[0039] The reactive gas is allowed to flow into chamber 1 through a gas inlet configuration 15, consumed reactive gas is suctioned off at a pumping opening 17. As shown with G, a gas flow through the chamber 1 parallel to axes A of the plasma beams is preferably targeted.

[0040] By means of Helmholtz coils 19 in the chamber 1, further a magnetic field H is generated substantially parallel to beam axes A, by means of which the local plasma density distribution can additionally be tuned.

[0041] In FIGS. 3 to 6 in top view and schematically, the configurations of plasma beams 3 are depicted, with deposition surfaces 13 guided in between according to the invention and defined by workpiece support 13 a or collection surfaces.

[0042] In FIG. 5, again in top view, a further configuration of six plasma beams 3 with deposition surface 13 is shown, which is guided such that on it bilaterally a desired plasma density distribution is effected, in this case with minimum inhomogenity.

[0043] In FIG. 5, further, is shown in dashed lines the way in which, apart from the deposition surface 13, guided between the plasma beams 3, upon which action takes place bilaterally, between the plasma beams 3 and the recipient or chamber wall further deposition surfaces 14 can be disposed, which are only on one side exposed to the treatment. For the workpiece treatment are correspondingly provided on the one deposition surface 13 workpieces to be treated, in particular to be coated on two or all sides, on the deposition surfaces 13 a only workpieces to be treated, in particular to be coated, on one side.

[0044] In FIG. 7, as a function of the heating current I, the plasma density distribution is shown resulting from two plasma beams spaced apart. If a planar deposition surface is placed parallel to the plane of drawing of FIG. 7 into a region such that at this surface plasma density maxima occur of 20% of the maximum plasma densities obtaining in beam axis A, the plasma density distribution along this surface results, which is plotted qualitatively at d. In a depiction analogous to FIG. 1, such a plasma density distribution is shown modeled in FIG. 8, again at (a) with an assumed linear dependence of the plasma density on the arc axis distance x, at (b) with an assumed quadratic one.

[0045] The less the plasma density utilized at the provided deposition surfaces, relative to the maximum plasma density in beam axes A, the more homogeneous, i.e. equally distributed, becomes the plasma density distribution. But that simultaneously at only approximately 20% of the plasma density utilization nevertheless very high deposition rates of at least 400 nm/min at temperatures of maximally 500° C. can be attained, is surprising.

[0046] As depicted with ω in FIG. 3 and in FIG. 6 a further homogenation of the realized deposition distribution can be attained, in particular in coating, thereby that the workpieces are rotated about an axis Ar, preferably substantially perpendicularly to the beam axes A, and/or, as shown in FIG. 6, can be moved linearly along the beam axes depicted in FIG. 6 with the double arrow F.

[0047] As described in the introduction, with the introduced installations according to the invention or the methods according to the invention, it is made possible within the framework of a workpiece treatment, to deposit, on the one hand, difficult to produce layers, in particular diamond layers, over large areas with largely constant layer thickness distribution or to deposit with very high deposition rates and low temperatures reactive layers, in particular also layers comprised of silicon compounds, in particular of microcrystalline μC—Si:H, preferably employing silane as the reactive gas. But, on the other hand, it is also possible to deposit through the corresponding setting of the discharge parameters said materials as powder or clusters on said deposition surfaces. 

What is claimed is:
 1. A vacuum treatment installation, comprising: a vacuum treatment chamber (1); a plasma discharge configuration in the chamber; as a gas supply configuration connected to the chamber; the plasma discharge configuration having at least two plasma beam discharge configurations (5, 9) with substantially parallel discharge axes (A) and at least one deposition configuration positioned along a surface (13) which extends at selected distances from the beam axes (A) and along a substantial section of the discharge beam longitudinal extension; a gas suction configuration connected to the chamber; the gas supply configuration (15) and the gas suction configuration (17) being connected to the vacuum chamber (1) such that a gas flow (G) through the chamber (1) is generated, which is substantially parallel to the discharge axes (A), and the deposition configuration is disposed between the discharge axes and/or the discharge axes (A) are disposed between two deposition configurations facing one another.
 2. An installation as claimed in claim 1, wherein at least one deposition configuration is formed by a workpiece support configuration for one or several workpieces (13 a).
 3. An installation as claimed in claim 1, wherein at least one deposition configuration is formed by a substantially continuous planar configuration as a powder capture surface.
 4. An installation as claimed in claim 1, wherein gaps between the plasma beam discharge configuration gaps (5, 9) are low-voltage high-current arc discharge gaps.
 5. An installation as claimed in claim 4, wherein the gaps are driveable independently of one another.
 6. An installation as claimed in claim 5, wherein gaps are cold cathodes.
 7. An installation as claimed in claim 5, wherein gaps are hot cathodes (5).
 8. An installation as claimed in claim 1, wherein the gas supply configuration (15) is connected to a gas tank configuration containing at least one of a carbon-, boron-, nitrogen-, hydrogen- or silicon-containing gas.
 9. A method of using the installation as claimed in claim 1, comprising the step of depositing metastable materials.
 10. A method as claimed in claim 9, wherein the metastable materials is at least one of cBN, α-Al2O3, C3N4, diamond material or microcrystalline silicon compounds.
 11. A method as claimed in claim 10, wherein the microcrystalline silicon compound is μC—Si:H.
 12. A method for producing vacuum-treated workpieces, in which in a vacuum atmosphere at least two plasma beams with substantially parallel beam axes are generated, a workpiece surface to be treated as the deposition surface is disposed along a surface in the vacuum atmosphere, on which by the plasma beams a predetermined plasma density distribution is generated, and reactive gas is allowed to flow into the vacuum atmosphere, and gas is pumped from the vacuum atmosphere, comprising the steps of: generating a gas flow in the vacuum atmosphere, directed substantially parallel to the beam axes, and disposing workpiece surfaces facing away from one another between the plasma beams and/or workpiece surfaces facing one another such that they include the plasma beams between them.
 13. A method as claimed in claim 12, wherein a silicon compound is deposited onto the deposition surface.
 14. A method as claimed in claim 13, wherein the compound if microcrystalline silicon μC—Si:H, and therein silane, is employed as a reactive gas.
 15. A method as claimed in claim 12, wherein onto the deposition surface is deposited metastable material.
 16. A method as claimed in claim 15, wherein metastable material is at least one of cBN, α-Al2O3, C3N4 or diamond.
 17. A method as claimed in claim 12, wherein the plasma beams are generated as low-voltage arc discharges.
 18. A method as claimed in claim 17, wherein the plasma beams are generated as high-current arc discharges.
 19. A method as claimed in claim 18, wherein the plasma beams are generated by means of cold cathode discharges.
 20. A method as claimed in claim 12, wherein the plasma beams are generated by means of hot cathode discharges.
 21. A method as claimed in claim 12, wherein the deposition surface is disposed in the vacuum atmosphere and with respect to the plasma beams such that predetermined minimum plasma density fluctuations occur along the surface.
 22. A method as claimed in claim 21, wherein, along said surface, plasma densities of maximally 20% occur, and specifically in regions in each instance closest to the plasma beam, with respect to the plasma density maxima of the closest plasma beams.
 23. A method as claimed in claim 22, wherein the maximum is 10%.
 24. A method as claimed in claim 23, wherein the maximum is 5%.
 25. A method as claimed in claim 12, wherein the plasma beam discharges is operated independently of one another.
 26. A method as claimed in claim 12, wherein, with the disposition of the deposition surface such that plasma density maxima obtaining on it are 20% of the particular closest beam plasma density maxima, a deposition rate on the deposition surface of at least 400 nm/min is set, at a deposition surface temperature of maximally 500° C.
 27. A method as claimed in claim 26, wherein the plasma density distribution is tuned by means of at least one magnetic field parallel to the beam axes.
 28. A method as claimed in claim 12, wherein several workpieces are disposed along the surface and they are rotated about axes of rotation and/or moved linearly at least approximately parallel to the beam axes, in pendulum motions back and forth.
 29. A method for the production of powder out of a reactive gas excited by means of plasma discharge in a vacuum atmosphere, comprising the steps of: generating at least two plasma beams in the vacuum atmosphere with substantially parallel beam axes and a collection surface as the deposition surface—for the powder is disposed in the vacuum atmosphere substantially parallel to the plasma beams such that on it a predetermined plasma density distribution is generated by the plasma beams.
 30. A method as claimed in claim 29, wherein a silicon compound is deposited onto the deposition surface.
 31. A method as claimed in claim 30, wherein the compound if microcrystalline silicon μC—Si:H, and therein silane, is employed as a reactive gas.
 32. A method as claimed in claim 29, wherein onto the deposition surface is deposited metastable material.
 33. A method as claimed in claim 32, wherein metastable material is at least one of cBN, α-Al2O3, C3N4 or diamond.
 34. A method as claimed in claim 29, wherein the plasma beams are generated as low-voltage arc discharges.
 35. A method as claimed in claim 34, wherein the plasma beams are generated as high-current arc discharges.
 36. A method as claimed in claim 35, wherein the plasma beams are generated by means of cold cathode discharges.
 37. A method as claimed in claim 29, wherein the plasma beams are generated by means of hot cathode discharges.
 38. A method as claimed in claim 29, wherein the deposition surface is disposed in the vacuum atmosphere and with respect to the plasma beams such that predetermined minimum plasma density fluctuations occur along the surface.
 39. A method as claimed in claim 38, wherein, along said surface, plasma densities of maximally 20% occur, and specifically in regions in each instance closest to the plasma beam, with respect to the plasma density maxima of the closest plasma beams.
 40. A method as claimed in claim 39, wherein the maximum is 10%.
 41. A method as claimed in claim 40, wherein the maximum is 5%.
 42. A method as claimed in claim 29, wherein the plasma beam discharges is operated independently of one another.
 43. A method as claimed in claim 29, wherein, with the disposition of the deposition surface such that plasma density maxima obtaining on it are 20% of the particular closest beam plasma density maxima, a deposition rate on the deposition surface of at least 400 nm/min is set, at a deposition surface temperature of maximally 500° C.
 44. A method as claimed in claim 43, wherein the plasma density distribution is tuned by means of at least one magnetic field parallel to the beam axes.
 45. A method as claimed in claim 29, wherein several workpieces are disposed along the surface and they are rotated about axes of rotation and/or moved linearly at least approximately parallel to the beam axes, in pendulum motions back and forth. 